Universal Approach for Quantum Interfaces with Atomic Arrays

PRX Quantum Pub Date : 2024-05-07 DOI:10.1103/prxquantum.5.020329

Yakov Solomons, Roni Ben-Maimon, Ephraim Shahmoon

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Abstract

We develop a general framework for the analysis of two-sided quantum interfaces, composed of collections of atoms interacting with paraxial light. Accounting for photon-mediated dipole-dipole interactions, our approach is based on the mapping of collective atom-photon interfaces onto a generic one-dimensional model of light scattering, characterized by a reflectivity parameter

r_{0}

. This entails two key practical advantages: (i) the efficiency of the quantum interface in performing various quantum tasks, such as quantum memory or entanglement generation, is universally given by

r_{0}

and is hence reduced to a measurement or classical calculation of a reflectivity; (ii) the efficiency can be greatly enhanced by a properly designed photon mode that spatially matches a collective-dipole eigenmode of the atoms. We demonstrate our approach for realistic cases of finite-size atomic arrays, partially filled arrays, and circular arrays. This provides a unified approach for treating collective light-matter coupling in various platforms, such as optical lattices and optical tweezers.

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原子阵列量子界面的通用方法

我们开发了一个分析双面量子界面的通用框架，该界面由与同轴光相互作用的原子集合组成。考虑到光子介导的偶极-偶极相互作用，我们的方法基于将原子-光子集合界面映射到通用的一维光散射模型上，该模型以反射率参数 r0 为特征。这带来了两个关键的实际优势：(i) 量子界面在执行各种量子任务（如量子记忆或纠缠生成）时的效率普遍由 r0 给定，因此可简化为反射率的测量或经典计算；(ii) 通过适当设计光子模式，使其在空间上与原子的集体偶极子特征模式相匹配，可大大提高效率。我们针对有限尺寸原子阵列、部分填充阵列和圆形阵列的实际情况演示了我们的方法。这为处理光晶格和光镊子等各种平台中的集体光物质耦合提供了统一的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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